2014
DOI: 10.1088/1748-9326/9/6/064012
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Prospects for simulating macromolecular surfactant chemistry at the ocean–atmosphere boundary

Abstract: Biogenic lipids and polymers are surveyed for their ability to adsorb at the water-air interfaces associated with bubbles, marine microlayers and particles in the overlying boundary layer. Representative ocean biogeochemical regimes are defined in order to estimate local concentrations for the major macromolecular classes. Surfactant equilibria and maximum excess are then derived based on a network of model compounds. Relative local coverage and upward mass transport follow directly, and specific chemical stru… Show more

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Cited by 39 publications
(116 citation statements)
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“…[8,9] Film drops (,1 mm in diameter) produced by bursting of the bubble film efficiently transfer surface-active species that reside at the air-water interface into the atmosphere; this explains the presence of surfactants in fine SSA particles (,2.5 mm in diameter). [10] Given that the relative concentration of organic matter to inorganic salts in the ocean is extremely low (60-90 mM organic matter compared with approximately 460 000 mM Na þ ), [3] the high relative fraction of organic matter in SSA shows that the transfer of organic species from the ocean to SSA proceeds through selective processes. To better understand the biogeochemical connections between the ocean and atmosphere, it is critical to improve our understanding of the processes that control SSA composition in order to determine their effects on atmospheric chemistry and climate.…”
Section: Introductionmentioning
confidence: 99%
“…[8,9] Film drops (,1 mm in diameter) produced by bursting of the bubble film efficiently transfer surface-active species that reside at the air-water interface into the atmosphere; this explains the presence of surfactants in fine SSA particles (,2.5 mm in diameter). [10] Given that the relative concentration of organic matter to inorganic salts in the ocean is extremely low (60-90 mM organic matter compared with approximately 460 000 mM Na þ ), [3] the high relative fraction of organic matter in SSA shows that the transfer of organic species from the ocean to SSA proceeds through selective processes. To better understand the biogeochemical connections between the ocean and atmosphere, it is critical to improve our understanding of the processes that control SSA composition in order to determine their effects on atmospheric chemistry and climate.…”
Section: Introductionmentioning
confidence: 99%
“…Background humic acid mixes or freezes-in at a constant level reflective of the seawater source, and it is then modulated in bulk by the local porosity. Since this carbon pool is considered refractory [27][28][29]77], inputs and channel tightening are the only factors involved. By contrast, proteins and polysaccharides are injected even at a minimum by grazing or mortality processes, as determined by the network of routings (Appendices A and B).…”
Section: Baseline Resultsmentioning
confidence: 99%
“…A rich oceanic dissolved organic chemistry may in fact be driven independently by under-ice blooms [78][79]. The effects are parameterized here through variable mixed layer concentrations in springtime, set highest for the longer lived polysaccharides [28].…”
Section: Baseline Resultsmentioning
confidence: 99%
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